Evolution of insulin-like growth factor I (IGF-I): structure and expression of an IGF-I precursor from Xenopus laevis

By means of a cloning strategy employing the polymerase chain reaction, we have isolated and characterized cDNAs for Xenopus laevis insulin-like growth factor I (IGF-I). These cDNAs encode a primary IGF-I translation product of 153 residues that demonstrates considerable amino acid sequence similarity with IGF-IA peptides from other species. Fifty-seven of 70 residues of the mature protein are identical among human, rat, chicken, and Xenopus IGF-I, while less amino acid conservation is found at the COOH-terminus (25/35 identities) or at the NH2-terminus (24/48 identities) of the precursor protein. Despite the lower degree of structural similarity at the NH2-terminus, in vitro studies of IGF-I biosynthesis and proteolytic processing support a conserved function for the atypically long 48 residue NH2-terminal signal sequence in directing the nascent IGF-I peptide through the secretory pathway. The 5'-untranslated region of Xenopus IGF-I mRNA matches the human, rat, and chicken sequences in greater than 90% of 279 nucleotides. IGF-I mRNAs from all four species encode a conserved upstream open reading frame of 14 amino acids starting 240-250 nucleotides 5' to the translation start site, suggesting a possible role for this region in modulating IGF-I gene expression. The X. laevis IGF-I gene is transcribed and processed into three mRNAs of 1.6, 2.1, and 3.0 kilobases in liver, and IGF-I mRNAs can be detected in liver, lung, heart, kidney, and peritoneal fat of adult animals. These studies demonstrate that both the IGF-I protein precursor and potential regulatory regions of IGF-I mRNA have been conserved during vertebrate evolution, and indicate that like several other polypeptide growth factors, IGF-I may be of fundamental importance in regulating specific aspects of growth and development in all vertebrates.     

Structure and expression of a chicken insulin-like growth factor I precursor

Insulin-like growth factor I (IGF-I) is a 70 amino acid growth-promoting polypeptide whose sequence and functions have been highly conserved among mammals. As an initial step in defining the role of IGF-I in other vertebrate species, we have isolated and characterized an IGF-I cDNA from the chicken. This cDNA encodes a 153 amino acid primary translation product which resembles in structure and sequence the IGF-IA protein of mammals. There is strong amino acid conservation between chicken and mammalian IGF-I throughout the entire protein. Sixty of 70 amino acids are identical in mature IGF-I among the chicken, rat, and human peptides, with five differences being localized to the C domain, and two to the D region. A comparable degree of amino acid identity is found in the COOH-terminal extension peptide (28/35 residues). At the NH2-terminus, where there is more amino acid divergence (32/48 identities), the most 5'-AUG codon is the only methionine residue conserved among all three species, suggesting that it functions as the authentic translation initiation site, an observation supported by cell-free studies of biosynthesis and cotranslational proteolytic processing. The pattern of IGF-I gene expression appears to be simpler in chickens than in mammals, since a single predominant mRNA of 2.6 kilobases can be detected in liver polyadenylated RNA on Northern blots. In the chicken, as in rats and humans, IGF-I mRNA is synthesized in multiple tissues, including liver, brain, skeletal muscle, and heart.(ABSTRACT TRUNCATED AT 250 WORDS)     

Mutations in the NH2-terminal domain of the signal peptide of preproparathyroid hormone inhibit translocation without affecting interaction with signal recognition particle

The amino-terminal domain of a eukaryotic signal peptide, from bovine parathyroid hormone, was altered by in vitro mutagenesis of the cDNA. The function of "internalized" signal sequence mutants and of deletion mutants was assayed using an in vitro translation-translocation system. The addition of 11 amino acids to the NH2 terminus of the signal peptide did not prevent normal processing of the precursor protein, whereas a 23-amino acid extension blocked processing. These data suggest that the NH2-terminal sequences of internal signal peptides must be permissive of the signal function. Deletion of 6 NH2-terminal amino acids from the signal peptide had no effect on its cleavage by microsomal membranes, but removal of 10 or 13 amino acids, including all charged residues prior to the hydrophobic core, prevented processing. For both the extension and deletion mutations, processed proteins were protected from proteolytic digestion, whereas unprocessed forms were not, which indicated that the unprocessed mutant proteins were not translocated across the microsomal membrane. Translation of both the extension and deletion translocation-deficient mutants was arrested by signal recognition particle, and salt-washed microsomal membranes reversed the translational arrest. These data demonstrate that the NH2-terminal domain is not required for the interaction of signal recognition particle with the signal peptide or with signal recognition particle receptor, but is required for formation of a maximally translocation-competent complex with the microsomal membrane.     

Organ-specific and age-dependent expression of insulin-like growth factor-I (IGF-I) mRNA variants: IGF-IA and IB mRNAs in the mouse

Insulin-like growth factor-I (IGF-I) gene generates several IGF-I mRNA variants by alternative splicing. Two promoters are present in mouse IGF-I gene. Each promoter encodes two IGF-I mRNA variants (IGF-IA and IGF-IB mRNAs). Variants differ by the presence (IGF-IB) or absence (IGF-IA) of a 52-bp insert in the E domain-coding region. Functional differences among IGF-I mRNAs, and regulatory mechanisms for alternative splicing of IGF-I mRNA are not yet known. We analyzed the expression of mouse IGF-IA and IGF-IB mRNAs using SYBR Green real-time RT-PCR. In the liver, IGF-I mRNA expression increased from 10 days of age to 45 days. In the uterus and ovary, IGF-I mRNA expression increased from 21 days of age, and then decreased at 45 days. In the kidney, IGF-I mRNA expression decreased from 10 days of age. IGF-IA mRNA levels were higher than IGF-IB mRNA levels in all organs examined. Estradiol-17beta (E2) treatment in ovariectomized mice increased uterine IGF-IA and IGF-IB mRNA levels from 3 hr after injection, and highest levels for both mRNAs were detected at 6 hr, and relative increase was greater for IGF-IB mRNA than for IGF-IA mRNA. These results suggest that expression of IGF-I mRNA variants is regulated in organ-specific and age-dependent manners, and estrogen is involved in the change of IGF-I mRNA variant expression.     

Identification and characterization of a phospholipid-binding site of bovine factor Va

Coagulation factor Va is a cofactor which combines with the serine protease factor Xa on a phospholipid surface to form the prothrombinase complex. The phospholipid-binding domain of bovine factor Va has been reported to be located on the light chain of the molecule and more precisely on a fragment of Mr = 30,000 which is obtained after digestion of factor Va light chain by factor Xa. This proteolytic fragment is located in the NH2-terminal part of factor Va light chain (residues 1564-1765). In order to further characterize the lipid-binding domain of bovine factor Va, isolated bovine light chain was preincubated with synthetic phospholipid vesicles (75% phosphatidylcholine, 25% phosphatidylserine) and digested with trypsin, chymotrypsin, and elastase. Two peptide regions protected from proteolytic cleavage were identified and characterized from each proteolytic digestion. A comparison of the NH2-terminal sequence and amino acid composition of the two tryptic peptides with the deduced sequence of human factor V indicates a match with residues 1657-1791 of the light chain of human factor V for one peptide and residues 1546-1656 for the other peptide. When chymotrypsin or elastase were used for digestion, the NH2-terminal sequence of one peptide showed a match with residues 1667-1797 of the light chain, while the other peptide presented an NH2-terminal sequence identical with the previously described for the bovine factor Va light chain. When these peptides were assayed for direct binding to phospholipid vesicles, only the tryptic and the chymotryptic peptides covering the middle region of the A3 domain of the bovine factor Va light chain demonstrated an ability to interact with phospholipid vesicles. Thus, knowing that the factor Xa cleavage site on the factor Va light chain is located between residues 1765 and 1766 of the light chain this lipid-binding region of the bovine factor Va is further localized to amino acid residues 1667-1765.     

Biosynthesis of human preapolipoprotein A-IV

The primary translation product of human intestinal apolipoprotein A-IV mRNA was purified from ascites and wheat germ cell-free systems. Comparison of its NH2-terminal sequence with mature, chylomicron-associated apo-A-IV revealed that apo-A-IV was initially synthesized with a 20-amino acid long NH2-terminal extension: Met-X-Leu-X-Ala-Val-Val-Leu-X-Leu-Ala-Leu-Val-Ala-Val-Ala-Leu-X-X-Ala. Co-translational cleavage of the cell-free product as well as Edman degradation of the stable intracellular form of the protein recovered from Hep G2 cells indicated that this entire 20-amino acid sequence behaved as a signal peptide. There is at least 55% sequence homology between the rat and human apo-A-IV signal peptides and 33% homology between the human A-I and A-IV presegments. Agarose gel chromatography of Hep G2 culture media indicated that neither apo-A-IV nor -A-I is associated with particles that have physical properties resembling any of the plasma lipoprotein density classes. Incubation of plasma with Hep G2 media resulted in transfer of A-I but not A-IV to lipoproteins. Since the NH2 termini of co-translationally cleaved and chylomicron-associated apo-A-IV are identical, it is apparent that 1) this polypeptide does not undergo NH2-terminal post-translational proteolysis like proapo-A-II or proapo-A-I, and 2) regulation of A-IV-lipoprotein interaction is not dependent on any NH2-terminal proteolytic processing event.     

Structural features in the NH2-terminal region of a model eukaryotic signal peptide influence the site of its cleavage by signal peptidase

The 20-amino acid signal peptide of human pre (delta pro)apolipoprotein A-II contains the tripartite domain structure typical of eukaryotic prepeptides, i.e. a positively charged NH2-terminal (n) region, a hydrophobic core (h) region, and a COOH-terminal polar domain (c region). This signal sequence has multiple potential sites for cotranslational processing making it an attractive model for assessing the consequences of systematic structural alterations on the site selected for signal peptidase cleavage. We previously analyzed 40 mutant derivatives of this model preprotein using an in vitro translation/canine microsome processing assay. The results showed that the position of the boundary between the h and c regions and properties of the -1 residue are critical in defining the site of cotranslational cleavage. To investigate whether structural features in the NH2-terminal region of signal peptides play a role in cleavage specificity, we have now inserted various amino acids between the positively charged n region (NH2-Met-Lys) and the h region of a "parental" pre(delta pro)apoA-II mutant that has roughly equal cleavage between Gly18 decreases and Gly20 decreases. Movement of the n/h boundary toward the NH2 terminus results in a dramatic shift in cleavage to Gly18 decreases. Replacement of the Lys2 residue with hydrophilic, negatively charged residues preserves the original sites of cleavage. Replacement with a hydrophobic residue causes cleavage to shift "upstream." Simultaneous alteration of the position of n/h and h/c boundaries has an additive effect on the site of signal peptidase cleavage. None of these mutations produced a marked decrease in the efficiency of in vitro cotranslational translocation or cleavage. However, in sequence contexts having poor signal function, introduction of hydrophobic residues between the n and h regions markedly improved the efficiency of translocation/processing. We conclude that the position of the n/h boundary as well as positioning of the h/c boundary affects the site of cleavage chosen by signal peptidase.     

Cloning and expression of human arylsulfatase A

A full length cDNA for human arylsulfatase A was cloned and sequenced. The predicted amino acid sequence comprises 507 residues. A putative signal peptide of 18 residues is followed by the NH2-terminal sequence of placental arylsulfatase A. One of the arylsulfatase A peptides ends 3 residues ahead of the predicted COOH terminus. This indicates that proteolytic processing of arylsulfatase A is confined to the cleavage of the signal peptide. The predicted sequence contains three potential N-glycosylation sites, two of which are likely to be utilized. The sequence shows no homology to any of the known sequences of lysosomal enzymes but a 35% identity to human steroid sulfatase. Transfection of monkey and baby hamster kidney cells resulted in an up to 200-fold increase of the arylsulfatase A activity. The arylsulfatase A was located in lysosome-like structures and transported to dense lysosomes in a mannose 6-phosphate receptor-dependent manner. The arylsulfatase A cDNA hybridizes to 2.0- and 3.9-kilobase species in RNA from human fibroblasts and human liver. RNA species of similar size were detected in metachromatic leukodystrophy fibroblasts of two patients, in which synthesis of arylsulfatase A polypeptides was either detectable or absent.     

Proteolysis of ProPTHrP(1-141) by "prohormone thiol protease" at multibasic residues generates PTHrP-related peptides: implications for PTHrP peptide production in lung cancer cells

The parathyroid hormone-related protein (PTHrP) precursor requires proteolytic processing to generate PTHrP-related peptide products that possess regulatory functions in the control of PTH-like (parathyroid-like) actions and cell growth, calcium transport, and osteoclast activity. Biologically active peptide domains within the PTHrP precursor are typically flanked at their NH2- and COOH-termini by basic residue cleavage sites consisting of multibasic, dibasic, and monobasic residues. These basic residues are predicted to serve as proteolytic cleavage sites for converting the PTHrP precursor into active peptide products. The coexpression of the prohormone processing enzyme PTP ("prohormone thiol protease") in PTHrP-containing lung cancer cells, and the lack of PTP in cell lines that contain little PTHrP, implicate PTP as a candidate processing enzyme for proPTHrP. Therefore, in this study, PTP cleavage of recombinant proPTHrP(1-141) precursor was evaluated by MALDI mass spectrometry to identify peptide products and cleavage sites. PTP cleaved the PTHrP precursor at the predicted basic residue cleavage sites to generate biologically active PTHrP-related peptides that correspond to the NH2-terminal domain (residues 1-37) that possesses PTH-like and growth regulatory activities, the mid-region domain (residues 38-93) that regulates calcium transport, and the COOH-terminal domain (residues 102-141) that modulates osteoclast activity. Lack of cleavage at other types of amino acids demonstrated the specificity of PTP processing at basic residue cleavage sites. Overall, these results demonstrate the ability of PTP to cleave the PTHrP precursor at multibasic, dibasic, and monobasic residue cleavage sites to generate active PTHrP-related peptides. The presence of PTP immunoreactivity in PTHrP-containing lung cancer cells suggests PTP as a candidate processing enzyme for the PTHrP precursor.     

Primary structure of beta-galactoside alpha 2,6-sialyltransferase. Conversion of membrane-bound enzyme to soluble forms by cleavage of the NH2-terminal signal anchor

This report describes the primary structure of a rat liver beta-galactoside alpha 2,6-sialyltransferase (EC 2.4.99.1), a Golgi apparatus enzyme involved in the terminal sialylation of N-linked carbohydrate groups of glycoproteins. The complete amino acid sequence was deduced from the nucleotide sequence of cDNA clones of the enzyme. The primary structure suggests that the topology of the enzyme in the Golgi apparatus consists of a short NH2-terminal cytoplasmic domain, a 17-residue hydrophobic sequence which serves as the membrane anchor and signal sequence, and a large lumenal, catalytic domain. NH2-terminal sequence analysis of a truncated form of the enzyme, obtained by purification from tissue homogenates, reveals that it is missing a 63-residue NH2-terminal peptide which includes the membrane binding domain. These and supporting results show that soluble forms of the sialyltransferase can be generated by proteolytic cleavage between the NH2-terminal signal-anchor and the catalytic domain.     

Molecular cloning and nucleotide sequence of cDNA of microsomal carboxyesterase E1 of rat liver

cDNA clones of the mRNA for rat liver carboxyesterase E1, one of the carboxyesterases exclusively located on the luminal side of microsomal vesicles, were isolated. Sequence analysis of 2 kbp long cDNA revealed the primary structure of carboxyesterase E1, which consisted of 549 amino acids (Mr 60, 171.71) and contained an extra peptide of 18 amino acids at the NH2-terminus of the mature enzyme. Comparison of the deduced primary structure and sequences of some proteolytic fragments of the purified enzyme indicated the multiplicity of the enzyme. The extra peptide at the NH2-terminal had features in common with the signal peptides of most secretory proteins. However, no polar amino acid residues existed before the hydrophobic core of the signal peptide. A new interpretation is proposed to explain how the signal peptide without the NH2-terminal polar residues works. A tetrapeptide (KDEL) which was shown to keep a few microsomal proteins in the lumen of the endoplasmic reticulum was not found in the primary structure of carboxyesterase E1, which suggested the existence of another mechanism for retention of proteins in the lumen of endoplasmic reticulum. Carboxyesterase E1 showed significant homology with the COOH-terminal portion of thyroglobulin.     

Proteolytic processing and compartmentalization of the primary translation products of mammalian apolipoprotein mRNAs

The steps involved in the initial assembly of apolipoproteins and lipids into supramolecular arrays (nascent lipoprotein particles) are largely unknown. Examination of the proteolytic processing and compartmentalization of the primary translation products of apolipoprotein mRNAs represents one approach to deciphering the molecular details of lipoprotein assembly. The structures of the primary translation products of seven mammalian apolipoprotein mRNAs has been determined in the past several years. The organization of apolipoprotein signal peptides is typical of eukaryotic prepeptides, although an unusual degree of sequence conservation is present among the signal segments of apo AI, AIV, and E. For those apolipoprotein sequences studied in detail, SRP-dependent cotranslational translocation and proteolytic processing appears to be highly efficient and results in sequestration of the processed protein within the lumen of the endoplasmic reticulum (ER). However the mechanism by which these lipid-binding proteins avoid arrest during their translocation through the lipid bilayer of the ER membrane remains obscure. The two principal human HDL apolipoproteins undergo novel extracellular post-translational proteolytic processing, which results in removal of nonhomologous propeptides. The proteases responsible for proapo AI and AII processing appear to be different. The processing of these proapolipoproteins provides a potential series of steps for regulating the ordered assembly of HDL constituents.     

Interactions of amino terminal domains of Shaker K channels with a pore blocking site studied with synthetic peptides

Synthetic peptides of the five alternative NH2-terminal sequences of Shaker when applied to the cytoplasmic side of ShB channels that have an NH2-terminal deletion (ShB delta 6-46) block the channel with potencies correlated with the rate of inactivation in the corresponding variant. These peptides share no sequence similarity and yet three out of the five have apparent dissociation constants between 2 and 15 microM, suggesting that the specificity requirements for binding are low. To identify the primary structural determinants required for effective block of ShB delta 6-46, we examined the effects of substitutions made to the 20 residue ShB peptide on association and dissociation rates. Nonpolar residues within the peptide appear to be important in stabilizing the binding through hydrophobic interactions. Substitutions to leucine-7 showed there was a clear correlation between hydrophobicity and the dissociation rate constant (koff) with little effect on the association rate constant (kon). Substituting charged residues for hydrophobic residues within the region 4-8 disrupted binding. Within the COOH-terminal half of the peptide, substitutions that increased the net positive charge increased kon with relatively small changes in koff, suggesting the involvement of long-range electrostatic interactions in increasing the effective concentration of the peptide. Neutralizing charged residues produced small changes in koff. Charges within the region 12-20 act equivalently; alterations which conserved net charge produced little effect on either kon or koff. The results are consistent with this region of the peptide having an extended conformation and suggest that when bound this region makes few contacts with the channel protein and remains relatively unconstrained. Analogous mutations within the NH2-terminal domain of the intact ShB channel produced qualitatively similar effects on blocking and unblocking rates.     

Structure of human erythrocyte spectrin. I. Isolation of the alpha-I domain and its cyanogen bromide peptides

The alpha-I domain of human erythrocyte spectrin was produced by a mild tryptic digestion of the intact molecule and purified by a single step affinity chromatography procedure using a monoclonal antibody. A tryptic peptide representing the alpha-I domain, which migrated on polyacrylamide gels as an 80,000-dalton peptide, was subjected to automated Edman-Begg degradation. Products from automated sequencing were identified by reverse-phase high performance liquid chromatography. Two smaller proteolytic products of the alpha-I domain (T74 and T50) were also subjected to automated sequence analysis. CNBr cleavage of the alpha-I domain produced nine unique peptides which were separated by gel filtration on a high performance liquid chromatograph. Peptides were further purified by reverse-phase chromatography and characterized by amino acid analysis. Partial sequences were determined by automated NH2-terminal sequence analysis. A single aspartate-proline bond, which was partially hydrolyzed during the cyanogen bromide cleavage reaction, was also identified. These sequence data include the first 86 residues of the alpha-I domain, and the spectrin oligomer binding site has been tentatively localized within the first 39 residues. The sequence of 293 residues of a total 633 residues in the alpha-I domain is presented and represents the first structural information for this protein.     

Biosynthesis of human preproapolipoprotein A-II

The primary translation product of human apolipoprotein A-II was purified from wheat germ and ascites cell-free lysates programmed with RNA isolated from either a hepatocellular carcinoma cell line (HepG2) or intestinal epithelium. A-II mRNA represents 0.2% of the translatable RNA in these hepatocytes and in jejunal epithelium. Plasma high density lipoprotein-associated A-II is a 77-amino acid polypeptide. The primary translation product is 100 amino acids long and contains a 23-amino acid NH2-terminal extension. Cotranslational cleavage of the cell-free product indicated that this NH2-terminal sequence consists of an 18-amino acid long signal peptide, Met-Lys-Leu-Leu-Ala-Ala-X-Val-Leu-Leu-Leu-X-X-Cys-X-Leu-X-X-, and a 5-amino acid long propeptide, Ala-Leu-Val-Arg-Arg. This functional division was confirmed by sequencing the stable intracellular form of apolipoprotein A-II isolated from HepG2 cells. Approximately 45% of the proapo-A-II is cleaved to the mature form during export from HepG2 cells. The COOH-terminal dipeptide conforms to the rule that prosegments are cleaved after paired basic residues. We have previously shown (Gordon, J. I., Sims, H. F., Lentz, S. R., Edelstein, C., Scanu, A. M., and Strauss, A. W. (1983) J. Biol. Chem. 258, 4037-4044) that proapolipoprotein A-I is not cleaved during export from these cells and contains a prosegment with a COOH-terminal Gln-Gln dipeptide. Therefore, proteolytic processing of the two principal high density lipoprotein-associated apolipoproteins proceeds along different pathways.     

Assembly of the sarcoplasmic reticulum. Cell-free synthesis of te Ca2+ + Mg2+-adenosine triphosphatase and calsequestrin

Polyadenylated RNA prepared from neonatal rat muscle was translated in a rabbit reticulocyte cell-free system. Two sarcoplasmic reticulum proteins, the Ca2+ + Mg2+-dependent adenosine triphosphatase (ATPase) and calsequestrin, were isolated from the translation mixture by immunoprecipitation, followed by electrophoresis in sodium dodecyl sulfate-polyacrylamide gels. The [35S]methionine-labeled translation products were characterized by molecular weight, peptide mapping, and NH2-terminal sequence analysis. The ATPase synthesized in the cell-free system was found to have the same molecular weight (Mr = 100,000) and [35S]-methionine-labeled peptide map as the mature ATPase. The methionine residue present at the NH2 terminus of the mature ATPase was donated by initiator methionyl-tRNArMet and it became acetylated during translation. These results suggest that the ATPase was synthesized without an NH2-terminal signal sequence. Calsequestrin (Mr - 63,000) was synthesized as a higher molecular weight precursor (Mr = 66,000) that contained an additional [35S]methionine-labeled peptide when compared to mature calsequestrin. The NH2-terminal sequence of the precursor was different from the mature protein. The precursor was processed to a polypeptide with a molecular weight identical with mature calsequestrin when microsomal membranes prepared from canine pancreas were included during translation. These results show that calsequestrin is synthesized with an NH2-terminal signal sequence that is removed during translation. These data add to the evidence that the ATPase and calsequestrin follow distinctly different biosynthetic pathways, even though, ultimately, they are both located in the same membrane.     

Isolation and sequencing of a cDNA clone encoding acid phosphatase in rat liver lysosomes

A full length cDNA for acid phosphatase in rat liver lysosomes was isolated and sequenced. The predicted amino acid sequence comprises 423 residues (48,332 Da). A putative signal peptide of 30 residues is followed by the NH2-terminal sequence of lysosomal acid phosphatase (45,096 Da). The deduced NH2-terminal 18-residue sequence is identical with that determined directly for acid phosphatases purified from the rat liver lysosomal membranes. The primary structure deduced for acid phosphatase contains 9 potential N-glycosylation sites and a hydrophobic region which could function as a transmembrane domain. It exhibits 89% and 67% sequence similarities in amino acids and nucleic acids, respectively, to human lysosomal acid phosphatase. The amino acid sequence of the putative transmembrane segment shows a complete similarity to that of the human enzyme. Northern blot hybridization analysis identified a single species of acid phosphatase mRNA (2.2 kbp in length) in rat liver.     

Amino-terminal sequence of chicken preproalbumin

Poly(A)-containing RNA was isolated from chicken liver and translated in a reticulocyte lysate protein-synthesizing system in the presence of radiolabeled amino acids. Chicken albumin was isolated from the translation products by immunoprecipitation and subjected to automated Edman radiosequencing. Comparison with the sequence of proalbumin showed that the translocation product (preproalbumin) contains an NH2-terminal extension of 18 amino acid residues. The NH2-terminal sequence of chicken preproalbumin was as follows: Met-18-Lys-Asn-Val-15-Thr-Leu-Ile-Ser-Phe-10-Ile-Phe-Leu-Phe-Ser-5-Ser-Ala-Thr- Ser-1-Arg1, where Arg1 represents the NH2-terminal residue of proalbumin. This NH2-terminal extension is very rich in hydrophobic amino acid residues and is similar to the signal sequences found in other secreted proteins. The signal sequence of chicken preproalbumin shows considerable homology with the signal sequences of rat and bovine preproalbumins, but little homology with the signal sequences of other chicken preproteins.